Uv sanitizing apparatus

ABSTRACT

A portable sanitizing apparatus, such as a case, includes a first case portion arranged to receive an object to be sanitized, and a second case portion connected to the first case portion and including at least one UV light source configured to emit UV electromagnetic radiation. The second case portion includes an expansion member having a collapsed configuration and an expanded configuration. When the expansion member is in the expanded configuration, a distance between the second case portion and the first case portion is increased compared to when the expansion member is in the collapsed configuration, thereby increasing a distance from the at least one UV light source to the object to be sanitized.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. provisional application Ser.No. 62/866,226 filed Jun. 25, 2019, the disclosure of which is herebyincorporated in its entirety by reference herein.

TECHNICAL FIELD

Embodiments relate to a portable sanitizing apparatus which usesultraviolet light to sanitize objects and surfaces.

BACKGROUND

For better or worse, people take their smartphones, tablets, and otherelectronic devices everywhere. On average, mobile devices such as thesemay be handled approximately one hundred times per day and are used inthe car, the office, the gym, the kitchen, and the bathroom, too.Unsurprisingly, electronic devices easily become contaminated, wherecell phones can harbor nearly 20,000 distinct types of bacteria, germsand viruses. In order to prevent the spread of such microorganisms orpathogens, the surfaces of mobile devices should be kept clean. Inaddition to mobile devices, items such as credit cards, keys, watches,and other small objects which are frequently touched can also benefitfrom sterilization. While disinfecting liquids or wipes may be used forthis purpose, these are often not items that people carry with them atall times, and the chemicals in these products may not be desirable forthe consumer.

SUMMARY

In one or more embodiments, a portable sanitizing case includes a firstcase portion arranged to receive an object to be sanitized, and a secondcase portion connected to the first case portion and including at leastone UV light source configured to emit UV electromagnetic radiation. Thesecond case portion includes an expansion member having a collapsedconfiguration and an expanded configuration. When the expansion memberis in the expanded configuration, a distance between the second caseportion and the first case portion is increased compared to when theexpansion member is in the collapsed configuration, thereby increasing adistance from the at least one UV light source to the object to besanitized.

In one or more embodiments, a portable sanitizing wand includes a tophousing portion including at least one UV light source configured toemit UV electromagnetic radiation, and a base portion arranged to beplaced over a surface or object to be sanitized. An expansion member isconnected between the top housing portion and the base portion, theexpansion member having a collapsed configuration and an expandedconfiguration. When the expansion member is in the expandedconfiguration, a distance between the top housing portion and the baseportion is increased compared to when the expansion member is in thecollapsed configuration, thereby increasing a distance from the at leastone UV light source to the surface or object to be sanitized.

In one or more embodiments, a portable sanitizing case includes a firstcase portion arranged to receive an object to be sanitized, and a secondcase portion connected to the first case portion and including at leastone UV-C LED configured to emit UV electromagnetic radiation, whereinthe second case portion includes a mode button for activating a firstsanitizing mode and a second sanitizing mode of the at least one UV-CLED. In the first sanitizing mode, the at least one UV-C LED is suppliedwith a first current, and in the second sanitizing mode the at least oneUV-C LED is supplied with a second current which is greater than thefirst current and which overdrives the at least one UV-C LED to increasea radiant flux energy created for sanitizing the object.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a UV sanitizing case in a collapsedconfiguration according to one or more embodiments;

FIG. 2 is a front side view of the collapsed UV sanitizing case;

FIG. 3 is a rear side view of the collapsed UV sanitizing case;

FIG. 4 is a left side view of the collapsed UV sanitizing case;

FIG. 5 is a right side view of the collapsed UV sanitizing case;

FIG. 6 is a top end view of the collapsed UV sanitizing case;

FIG. 7 is a perspective view of the collapsed UV sanitizing case in anopen position;

FIG. 8 is a side view of the collapsed UV sanitizing case in an openposition;

FIG. 9 is a perspective view of the collapsed UV sanitizing case in anopen position with a mobile device received therein;

FIG. 10 is a schematic representation of exemplary UV-C LED placementand intensity in a UV sanitizing apparatus according to one or moreembodiments;

FIG. 11 is an illustration of a single UV-C LED which may be utilized ina UV sanitizing apparatus according to one or more embodiments;

FIG. 12 is a perspective view of a UV sanitizing case in an expandedconfiguration according to one or more embodiments;

FIG. 13 is a side perspective view of the expanded UV sanitizing case;

FIG. 14 is a left side view of the expanded UV sanitizing case;

FIG. 15 is a right side view of the expanded UV sanitizing case;

FIG. 16 is a top end view of the expanded UV sanitizing case;

FIG. 17 is an exploded view of the UV sanitizing case according to oneor more embodiments;

FIG. 18 is an illustration of an expanded UV sanitizing case inoperation with a mobile device received therein according to one or moreembodiments;

FIG. 19 is a schematic representation of an example light angle,distance to treated surface, and coverage area for a UV LED in a UVsanitizing apparatus according to one or more embodiments;

FIG. 20 is a schematic representation of an example coverage area for aUV LED with a light diffuser in a UV sanitizing apparatus according toone or more embodiments;

FIG. 21 is a perspective view of a UV sanitizing case with a first caseportion detached according to one or more embodiments;

FIG. 22 is a block diagram illustrating the control electronics for a UVsanitizing apparatus according to one or more embodiments;

FIG. 23 is an end perspective view illustrating a safety feature of theUV sanitizing case according to one or more embodiments;

FIG. 24 illustrates a magnetic safety feature of the UV sanitizing caseaccording to one or more embodiments;

FIG. 25 is a perspective view illustrating a charging port of the UVsanitizing case according to one or more embodiments;

FIG. 26 is a perspective view of a larger UV sanitizing case, such asfor a tablet, in a collapsed configuration according to one or moreembodiments;

FIG. 27 is a perspective view of the UV sanitizing case of FIG. 26 in anexpanded configuration;

FIG. 28 is a schematic representation of exemplary UV-C LED placementand intensity in a UV sanitizing apparatus according to one or moreembodiments;

FIG. 29 is a perspective view of a UV sanitizing bag according to one ormore embodiments;

FIG. 30 is an illustration of interior components of the UV sanitizingbag including a base, clips, and platform according to one or moreembodiments;

FIG. 31 is a perspective view of a mobile device held in position byclips received by the base;

FIG. 32 is a perspective view of an exemplary object, a pacifier,positioned on the platform received by the base;

FIG. 33 is a perspective view of a magnetic safety feature of a UVsanitizing apparatus in an off position according to one or moreembodiments;

FIG. 34 is a side view of the magnetic safety feature of FIG. 33 in anon position;

FIG. 35 is an illustration of a power button and indicator light for aUV sanitizing apparatus according to one or more embodiments;

FIG. 36 is an illustration of a UV sanitizing bag in operation with amobile device received therein according to one or more embodiments;

FIG. 37 is a perspective view of a UV sanitizing wand in a collapsedconfiguration according to one or more embodiments;

FIG. 38 is a side view of the collapsed UV sanitizing wand;

FIG. 39 is a front view of the collapsed UV sanitizing wand;

FIG. 40 is a top view of a UV sanitizing wand according to one or moreembodiments;

FIG. 41 is a bottom perspective view of a UV sanitizing wand accordingto one or more embodiments;

FIG. 42 is a bottom view of a UV sanitizing wand according to one ormore embodiments;

FIG. 43 is a perspective view of a UV sanitizing wand in an expandedconfiguration according to one or more embodiments;

FIG. 44 is a side view of the expanded UV sanitizing wand;

FIG. 45 is a front view of the expanded UV sanitizing wand; and

FIG. 46 is an exploded view of a UV sanitizing wand according to one ormore embodiments.

DETAILED DESCRIPTION

As required, detailed embodiments of the present invention are disclosedherein; however, it is to be understood that the disclosed embodimentsare merely exemplary of the invention that may be embodied in variousand alternative forms. The figures are not necessarily to scale; somefeatures may be exaggerated or minimized to show details of particularcomponents. Therefore, specific structural and functional detailsdisclosed herein are not to be interpreted as limiting, but merely as arepresentative basis for teaching one skilled in the art to variouslyemploy the present invention.

Disclosed herein are various embodiments of a portable sanitizingapparatus which uses ultraviolet (UV) light to sanitize objects andsurfaces. With reference to FIGS. 1-9 , a UV sanitizing case 10 isillustrated. In FIGS. 1-6 , the case 10 is shown in a closed, collapsedposition, whereas in FIGS. 7-9 the case 10 is depicted in an open,collapsed position. As illustrated, the case 10 may be generallyrectangular in shape and may be sized to receive a mobile device 12,such as a smartphone (FIG. 9 ). In one or more embodiments, the case 10is designed to fit all smartphones, regardless of size, make or model.In one non-limiting example, the case may be approximate 7-8 inches longand approximately 4-5 inches wide.

It is understood that different sizes and shapes of the case 10 may beprovided to accommodate different types of mobile devices which, inaddition to smartphones, may include tablets, computers, gaming devices,or other portable electronic devices. Still further, the case 10 couldbe configured to receive and sanitize devices other types of items suchas, but not limited to, credit cards, glasses, watches, earphones, keys,wallet, utensils, pacifiers, baby toys, jewelry, hair accessories,combs, brushes, make-up accessories, pens, computer mouse, remotecontrols, and many other objects.

The case 10 may be constructed from plastic (e.g. polycarbonate (PC),thermoplastic polyurethane (TPU)), rubber, or metallic materials, andoptionally may include a cloth or leather exterior cover. The plasticparts may include an antibacterial additive that helps with keeping thesurfaces of the case 10 free of microbial activity. Plastics additivesmay include, but are not limited to, silver-based antimicrobial agentslike AGION®, Microban antimicrobial plastic additives, and/or BiomasterTD100.

The case 10 includes a first case portion 14 arranged to receive anobject to be sanitized, such as a mobile device 12. As best shown inFIGS. 7-8 , the first case portion 14 includes a generally flat base 16and optionally may include a sidewall structure 18 integrally formedwith and extending upwardly from the base 16, defining a cavity 20. Aninner surface 22 of the base 16 is arranged to removably receive theobject to be sanitized. In one or more embodiments, the base innersurface 22 can be lined with an antimicrobial fabric. A second caseportion 24 is connected to the first case portion 14, such as via ahinge 26. The first case portion 14 may be secured to the second caseportion 24 via a zipper 28 around the perimeter of the case 10 or by analternative mechanism, such as a latch 30.

The second case portion 24 includes a housing 32 with controlelectronics including a microcontroller unit (MCU) 34 (best shown inFIG. 22 ). A power source 36, such as a rechargeable lithium-ionbattery, may also be mounted in the housing 32. Alternatively, the case10 could operate as a plug-in device. The second case portion 24 furtherincludes at least one light source 38, such as an LED, powered by thepower source 36 and controlled by the MCU 34, wherein the light source38 is configured to emit ultraviolet electromagnetic radiation forsanitizing contaminated surfaces. In one or more embodiments, theultraviolet radiation is in the range of ultraviolet-C (UV-C) light.UV-C is a range of electromagnetic radiation having a wavelength rangingfrom approximately 100 nm to approximately 280 nm, where UV-C light hasbeen demonstrated to be up to 99.9% effective in killing microorganismsincluding germs and bacteria. An inner wall 40 of the housing 32includes a plurality of apertures 42 sized and aligned to correspondwith the UV-C LEDs 38. Each aperture 42 includes transparent glass,plastic or other material to permit light from the LEDs 38 to passthrough.

The case 10 further includes a power button 44 in electricalcommunication with the MCU 34 for activating the LEDs 38, and alsooptionally the intensity and duration of operation of the LEDs 38. Thepower button 44 may be located anywhere on the case 10, such as on thetop surface 46 of the second case portion 24 as shown. The case 10 mayfurther include an indicator light 48 for displaying the charging statusof the battery 36 and the activation of the LEDs 38. In one non-limitingexample, the indicator light 48 could be flashing blue when the LEDs 38are operating and the sanitizing cycle is in progress, solid blue orturned off when the sanitizing cycle is complete, red when the battery36 is low, flashing green when the battery 36 is charging, and solidgreen when the battery 36 is fully charged. Instead or in addition tothe indicator light 48, the case 10 could include a progress indicator(not shown) such as a bar or dial to indicate cycle status, percentcompletion, and/or the state of charge of the battery 36.

The second case portion 24 includes a port 49 (FIGS. 13 and 25 ), suchas under a flap 50 on the top surface 46, for receiving a connector of acharging cable for charging the battery 36. In one non-limiting example,it is contemplated that approximately 70 sanitizing cycles may becompleted on a single charge of the battery 36. It is also contemplatedthat the case 10 could include a charging connector (not shown) withinthe first case portion 14 for charging a mobile device 12 from thebattery 36 while in the case 10.

FIG. 10 is a schematic representation of exemplary LED 38 placement,coverage area, and intensity in the UV sanitizing case 10 according toone or more embodiments, and FIG. 11 is an illustration of a single LED38 which may be utilized in the case 10. In the example shown, two LEDs38 may be used and spaced 80 mm apart. Further LED specifications mayinclude a radiant flux of 3.0 mW, a driving current of 20 mA, a forwardvoltage of 5.0 V, and a view angle 120 degrees, where each LED may havedimensions of 3.5 mm×3.5 mm×1.78 mm. Of course, these LED configurationsand specifications are not intended to be limiting, and alternative LEDconfigurations and specifications are also contemplated.

The LEDs 38 can have any shape and number and can be arranged in anymanner to provide optimal coverage for sanitizing the target surface.For example, the LEDs 38 can be spaced linearly along the housing innerwall 40 of the second case portion 24 or in other patterns to providethe desired coverage for sanitizing. Instead of separate LEDs 38, thelight source could include one or more elongated LED light pipes (notshown). Although LEDs 38 are shown herein in the second case portion 24,it is contemplated that LEDs 38 could also be provided in the first caseportion 14. It is further contemplated that the angle of the LEDs 38could be adjustable.

As indicated above, the power button 44 could also be used for modeselection between different sanitizing programs with different timingand different power/intensity settings. For example, a “standard”sanitizing mode may have the LEDs 38 supplied with a nominal current,for example, 100 mA. In a non-limiting example, the standard sanitizingmode may be activated with a short press of the power button 44 and mayhave a duration of approximately 30 seconds. Of course, it is understoodthat the sanitizing duration will be dependent on the number andplacement of LEDs 38 or other light sources.

A “super” sanitizing mode may also be provided and may includeoverdriving the current to the UV LEDs 38. For example, the LEDs 38 maybe supplied with a current of 120 mA (20% overdrive) to increase theradiant flux energy, and thereby increase antimicrobial efficacy andshorten cycle (treatment) time. In a non-limiting example, the supersanitizing mode may be activated with a long press of the power button44 and may have a duration of approximately 60 seconds. Overdriving anLED can push the power to as much as 5× its rated power. In anon-limiting example, if the LEDs 38 are rated at 3 mW, they may bedriven to 17.1 mW. That difference in radiant output results in aradiant flux of 5 over 30 seconds, whereas as much as 10 minutes wouldbe needed to reach the same value if these LEDs were still at 3 mW. Theintermittent use of an LED for a discrete timeframe enables it to bedriven by a higher current than the “constant on” rating and delivermore power to the irradiate the target surface, where all the LEDs 38 donot have to be working at all times.

In order to kill bacteria and germs effectively, UV light must come intocontact with the surface which is desired to be sanitized. In additionto light contact, the intensity of the UV light is important for theefficacy of the sanitization. When UV light reflects off any surface, itgreatly diminishes the UV light intensity. Therefore, to have effectiveand efficient sanitization, the LED light needs to be directed at thetarget surface and be spaced from the target surface a sufficientdistance to provide an optimal coverage area of the UV light. In onenon-limiting example, this distance may be approximately 30 mm from theLEDs 38 to the surface of the mobile device. However, a case having LEDsfixed at this distance from the device surface would be less compact andportable than desired.

Accordingly, the UV sanitizing case 10 includes an expansion member 52which can be expanded to increase the height of the second case portion24 above the first case portion 14, and thus increase the distance fromthe LEDs 38 to the target surface to be sterilized, such as on a mobiledevice 12. The expansion member 52 may be incorporated in the secondcase portion 24, and allows the second case portion 24 to be positionedan optimal distance from the target surface when the LEDs 38 areactivated while providing the ability to collapse and become compact forease of portability and storage of the case 10 when sanitizing iscompleted.

FIGS. 12-16 show the UV sanitizing case 10 in an expanded configuration,and FIG. 17 is an exploded view of the case 10 according to one or moreembodiments. The expansion member 52 may be opaque to prevent light frombeing transmitted through the case 10 and may have at least one fold 54.The expansion member 52 may be constructed from any material withsufficient flexibility to fold into the collapsed position as well asrigidity to remain in the expanded position such as, but not limited to,thermoplastic TPU, TPE, rubber, or silicone. It is contemplated that theexpansion member 52 could have varying height positions to providedifferent available distances from the LEDs 38 to the target surface.Tabs 56 may be provided on the second case portion 24 to facilitategripping the second case portion 24 for expanding the expansion member52. In one example, both sides of the case 10 do not have to expandequally.

In operation, as illustrated in FIG. 18 , a mobile device 12 or otherobject is inserted into the case 10, such as by unzipping the zipper 28and placing the mobile device 12 in the first case portion 14. The case10 may then be closed, such as by zipping the zipper 28. The expansionmember 52 is expanded after or prior to insertion of the mobile device12, such as by gripping the tabs 56 and pulling upward or outward. Theuser will depress the power button 44 to initiate the sanitizing cycle,activating the LEDs 38 and sanitizing the target surface. When theprogram is complete, the user can open (e.g. unzip) the case 10 and flipthe mobile device 12 over to sanitize the opposite surface, can removethe mobile device 12 from the case 10 for use, or can store the mobiledevice in the case 10.

FIG. 19 is a schematic representation of an example cone angle, distanceto treated surface, and coverage area for a UV LED in a UV sanitizingcase 10 or other apparatus according to one or more embodiments. Byusing the expansion member 52 (pop-up mechanism) described above,embodiments disclosed herein are capable of having the UV LEDs 38 orother light source optimally positioned at a controlled distance fromthe target surface being treated and considering the angle of vision ofthe LEDs 38 to maximize the UV coverage area.

FIG. 20 is a schematic representation of an example coverage area for aUV LED 38 with a light diffuser 57 included in a UV sanitizing case 10or apparatus, such as associated with the housing inner wall 40,according to one or more embodiments. Light diffusion removes the hotspot nature of an LED and instead spreads the light out evenly across anarea. The light diffuser 57 may be constructed from any diffusionmaterial which transfers the light energy as well as diffusing it suchas, but not limited to, types of translucent polycarbonate with lightdiffusion additives added for UV diffusion (e.g. TUFFAK® DX-NR). Inaddition, the housing inner wall 40 or other parts of the first caseportion 14 or second case portion 24 may include a reflective coating toreflect the UV-C rays and further increase coverage area, and may alsobe helpful for sanitizing objects with irregular shapes. Examples ofpossible reflective coatings are silver-based compounds, copper/nickelused as a middle layer and then coated with aluminum, and/or metallicmaterials, such as tantalum pentoxide (Ta2O5), aluminum oxide (Al2O3),or hafnium oxide (HfO2) that have high transmission in the LED emissionspectrum.

In one or more embodiments, the first case portion 14 and the secondcase portion 24 may be detachable from each other, where FIG. 21illustrates the UV sanitizing case 10 with the first case portion 14detached. In this way, the second case portion 24 can be used tosanitize a surface or object outside of the case 10. The second caseportion 24 can be attachable to/detachable from the first case portion14, for example, by a zipper 28, magnets, hook and loop material (e.g.VELCRO®), a snap-fit mechanism, a tongue and groove sliding mechanism,or other mechanisms.

The case 10 may be configured to automatically shut off the LEDs 38 ifthe MCU 34 detects that the case 10 is open. This safety feature avoidsaccidental illumination of UV light outside of the case 10, such as intoa user's eyes. FIG. 23 illustrates one embodiment of such a safetyfeature of the UV sanitizing case 10, where the MCU 34 is in electricalcommunication via cables 58 with a sensor 60 disposed at the edge of thesecond case portion 24 to sense if the case 10 is opened. Examples ofsuitable sensors include, but are not limited to, a mechanical switch, amagnetic hall sensor 62 (FIG. 22 ), an infrared sensor, and a positionsensor. As shown, the cables 58 may generally follow the contour of theexpansion member 52, although the sensor 60 is not limited to thelocation shown.

FIG. 24 illustrates a magnetic safety feature of the UV sanitizing case10 according to one or more embodiments. As shown, the zipper 28includes a zipper pull member 64 with an integrated magnet (not shown),and a corresponding magnet 66 is disposed on the case 10, such as on thesidewall structure 18 or hinge 26 area, adjacent an end of the zipper28. The magnet 66 is in communication with a magnetic hall sensor orswitch 62 (FIG. 22 ) which, in turn, is in electrical communication withthe MCU 34. In one or more embodiments, in order to execute thesanitizing cycle, the zipper 28 must be closed with the zipper pullmember 64 positioned on the magnet 66 in an “on” position. If the zipperpull member 64 is not positioned as such, each prior to or during asanitizing cycle, the hall sensor 62 is configured to communicate to theMCU 34 to prohibit or cease activation of the LEDs for the sanitizingcycle, acting as a safety lock. In this circumstance, the indicatorlight 48 may be used to indicate the error condition, such as byflashing red.

As another alternative safety feature, an accelerometer (not shown) maybe provided to provide orientation information for the case 10 so thatthe LEDs 38 may be deactivated if the second case portion 24 is facingupwardly or at another specified angle. As yet another alternative, aproximity sensor (not shown) may be provided for detecting the distanceto the surface to be disinfected, where the LEDs 38 may be turned off ifthe distance is beyond a predetermined threshold.

FIG. 26 is a perspective view of a larger UV sanitizing case 110, suchas for a tablet, in a collapsed configuration, and FIG. 27 illustratesthis case 110 in an expanded configuration. The compact and collapsibledesign of the sanitizing case functions as a carrying case for travelwith the ability to sanitize on-the-go. All of the description andfeatures of the UV sanitizing case 10 explained above may be equallyapplicable to this larger case 110. Like features may be designated withlike reference numerals with the addition of a “1” prefix.

FIG. 28 is a schematic representation of exemplary LED 138 placement,coverage area and intensity in the larger UV sanitizing case 110. Asshown, eight LEDs 138 may be used in two linear arrays of four LEDs 138each, with the LEDs 138 in each array spaced 70 mm apart and with thearrays spaced 107 mm from each other. Further LED specifications mayinclude a radiant flux of 17.2 mW, a driving current of 115 mA, aforward voltage of 5.4 V, and a view angle 120 degrees. Of course, theseLED configurations and specifications are not intended to be limiting,and alternative LED configurations and specifications are alsocontemplated.

FIG. 29 illustrates a UV sanitizing bag 210 which may sanitize mobiledevices or other electronics or objects while being soft, portable andcompact enough to easily fit in a purse or backpack. In one or moreembodiments, the bag 210 may have a bottom panel 268, a sidewallstructure 270 extending upwardly therefrom, and a top panel 272 whichdefine an internal cavity 274 into which objects to be sanitized may beinserted. A zipper 228 is provided to secure the top panel 272 to thesidewall structure 270 In one non-limiting example, the bag 210 may beapproximately 8 inches long and approximately 4 inches tall, althoughthese dimensions and the aforementioned panel and sidewall structure arenot intended to be limiting. Again, all of the description and featuresexplained above with reference to the UV sanitizing cases 10, 110 may beequally applicable to the sanitizing bag 210. Like features may bedesignated with like reference numerals with the addition of a “2”prefix.

FIGS. 30-32 illustrate several interior components of the UV sanitizingbag 210 including a base 276, one or more clips 278, and a platform 280which may each be constructed from a plastic material according to oneor more embodiments. The base 276 may be removably or permanentlyaffixed within the bag 210, such as along the bottom panel 268. Eitherthe clips 278 or the platform 280 may be removably and interchangeablyreceived by the base 276 and are arranged to hold items in positionwithin the bag 210. Such components may be desirable to keep items inplace and ensure optimal UV-C LED light exposure, maximizingeffectiveness of the sanitizing cycle. FIG. 31 illustrates a mobiledevice 12 held in position by clips 278, and FIG. 32 illustrates anexemplary object, a pacifier, positioned on the platform 280.

As described above with reference to FIG. 24 , FIGS. 33-34 illustrate amagnetic safety feature of the UV sanitizing bag 210 according to one ormore embodiments. The zipper 228 includes a zipper pull member 264 withan integrated magnet (not shown), and a corresponding magnet 266 isdisposed on the bag 210, such as on the sidewall structure 218 adjacentan end of the zipper 228. The magnet 266 is in communication with amagnetic hall sensor or switch 62 (FIG. 22 ) which, in turn, is inelectrical communication with the MCU 34. In one or more embodiments, inorder to execute the sanitizing cycle, the zipper 228 must be closedwith the zipper pull member 264 positioned on the magnet 266 in an “on”position (FIG. 34 ). If the zipper pull member 264 is not positioned assuch (FIG. 33 ), each prior to or during a sanitizing cycle, the hallsensor 62 is configured to communicate to the MCU 34 to prohibit orcease activation of the LEDs for the sanitizing cycle, acting as asafety lock.

Referring to FIGS. 29 and 35 , a flap 282 extending from the sidewallstructure 218 may function as a combined power button, mode selector,and indicator light, although other locations of the flap 282 on the bag210 are also contemplated. A charging port 249 may also extend from thesidewall structure 218 or another suitable location on the bag 210. Inone non-limiting example, a single charge of the battery 36 may allowfor approximately 18 sanitizing cycles. FIG. 36 is an illustration ofthe UV sanitizing bag 210 in operation with a mobile device 12 receivedtherein according to one or more embodiments. In the example shown, fourLEDs 238 may be used for sanitizing, two on each interior side of thebag 210, although other numbers and configurations of LEDs 238 are fullycontemplated.

As described above with reference to FIG. 21 , a UV sanitizing apparatusis contemplated which is not an enclosed case or bag. FIGS. 37-46illustrate a UV sanitizing wand 310 which can be placed over any surfaceor object to sanitize it. The wand 310 is lightweight, portable andcompact where, in one non-limiting example, the wand 310 may havedimensions of approximately 4-5 inches long and wide. All of thedescription and features provided above with reference to the UVsanitizing cases 10, 110 and the UV sanitizing bag 210 may be equallyapplicable to the sanitizing wand 310. Like features may be designatedwith like reference numerals with the addition of a “3” prefix.

In FIGS. 37-39 , the wand 310 is shown in a collapsed configuration, andin FIGS. 43-45 the wand 310 is shown in an expanded configuration. Thewand 310 includes top housing portion 384, a base portion 386, and anexpansion member 352 connected therebetween, wherein an inner surface ofthe expansion member 352 and the base portion 386 define a cavity 388arranged to removably cover an object or surface to be sanitized. In oneor more embodiments, the base portion 386 may include a wall structure390 with a bottom rim 392. In one non-limiting example, the bottom rim392 may have a width of approximately 5 mm. The bottom rim 392 isarranged to contact a surface, either on which an object to be sanitizedis placed or a surface which itself is to be sanitized. The bottom rim392 may provide a seal against the surface, prohibiting UV light fromescaping from the wand 310, providing safety, efficacy, and reliablepositioning.

The top housing portion 384 may serve as a grip for the user and housesthe control electronics and power source (e.g. MCU 34 and battery 36),such as described above with reference to FIG. 22 . The top housingportion 384 further includes at least one light source 338, such as anLED, powered by the power source 36 and controlled by the MCU 34,wherein the light source 338 is configured to emit ultravioletelectromagnetic radiation for sanitizing contaminated surfaces. An innerwall 340 of the top housing portion 384 includes a plurality ofapertures 342 sized and aligned to correspond with the UV-C LEDs 338.While three LEDs 338 are depicted herein, it is understood that the LEDs338 can have any shape and number and can be arranged in any manner toprovide optimal coverage for sanitizing the target surface.

The top housing portion 384 further includes a power button 344 inelectrical communication with the MCU 34 for activating the LEDs 338,and also optionally the intensity and duration of operation of the LEDs338. The wand 310 may further include an indicator light 348 fordisplaying the charging status of the battery 336 and the activation ofthe LEDs 338. The top housing portion 384 includes a port 349, such asunder a flap 350 on the top surface 46, for receiving a connector of acharging cable for charging the battery 336. A bottom cover 394 can beprovided which is arranged to fit over the bottom rim 392 when the wand310 is not in use (see FIG. 46 ).

The expansion member 352 can be expanded to increase the height of thetop housing portion 384, or the distance between the top housing portion384 and the base portion 386, and thus increase the distance from theLEDs 338 to the target surface to be sterilized. The expansion member352 allows inner wall 340 to be positioned an optimal distance from thetarget surface when the LEDs 338 are activated while providing theability to collapse and become compact for ease of portability andstorage of the wand 310 when sanitizing is completed.

To sanitize a surface or object, the expansion member 352 is expanded,such as by gripping the top housing portion 384 and pulling upward oroutward. Next, the power button 344 is depressed to initiate thesanitizing cycle. However, to ensure safe operation of the wand 310, anadditional step may be required in order to activate the LEDs 338. Inone or more embodiments, side buttons 396 may be provided on the tophousing portion 384 or another suitable location on the wand 310. Theside buttons 396 may be in electrical communication with a magnetic hallsensor or switch 62 (FIG. 22 ) which, in turn, is in electricalcommunication with the MCU 34 as described for previous embodiments.According to one or more embodiments, after depressing the power button(such as, but not limited to, within approximately 10 seconds), the LEDs338 will be activated only if both side buttons 396 are pressed andheld. If one or both of the side buttons 396 are released, the hallsensor 62 is configured to communicate to the MCU 34 to prohibit orcease activation of the LEDs 338 for the sanitizing cycle, acting as asafety lock. Once the LEDs 338 are activated, the wand 310 may be placedover any surface or object for sanitizing.

In this and other embodiments described above, the pop-up capabilityprovided by the expansion member allows the UV sanitizing apparatus toexpand and collapse in order to maximize UV light coverage and efficacyduring sanitization while offering a compact portable form when not inuse. It is understood that any UV sanitizing apparatus which utilizes anadjustable and/or collapsible and expandable elevation of the lightsource is fully contemplated, and is not limited to the shape, size,configuration, or form factors disclosed herein.

While exemplary embodiments are described above, it is not intended thatthese embodiments describe all possible forms of the invention. Rather,the words used in the specification are words of description rather thanlimitation, and it is understood that various changes may be madewithout departing from the spirit and scope of the invention.Additionally, the features of various implementing embodiments may becombined to form further embodiments of the invention.

1-8. (canceled)
 9. A portable sanitizing wand, comprising: a top housingportion including at least one UV light source configured to emit UVelectromagnetic radiation; a base portion arranged to be placed over asurface or object to be sanitized; and an expansion member connectedbetween the top housing portion and the base portion, the expansionmember having a collapsed configuration and an expanded configuration,wherein when the expansion member is in the expanded configuration, adistance between the top housing portion and the base portion isincreased compared to when the expansion member is in the collapsedconfiguration, thereby increasing a distance from the at least one UVlight source to the surface or object to be sanitized.
 10. The portablesanitizing wand of claim 9, wherein the top housing portion includes aninner wall in which the at least one UV light source is disposed, andthe inner wall, the expansion member and the base portion define acavity and are arranged to removably cover the surface or object to besanitized.
 11. The portable sanitizing wand of claim 9, wherein the tophousing portion includes a microcontroller unit and a battery disposedtherein.
 12. The portable sanitizing wand of claim 11, wherein the atleast one light source includes a UV-C LED powered by the battery andcontrolled by the microcontroller unit.
 13. The portable sanitizing wandof claim 11, wherein the top housing portion includes a power button inelectrical communication with the microcontroller unit for activatingthe at least one UV light source.
 14. The portable sanitizing wand ofclaim 11, further comprising side buttons provided on the top housingportion in electrical communication with the microcontroller unit forcontrolling activation of the at least one UV light source.
 15. Theportable sanitizing wand of claim 14, wherein continued depression ofthe side buttons is required in order to maintain activation of the atleast one UV light source.
 16. The portable sanitizing wand of claim 9,wherein the base portion includes a wall structure with a bottom rim.17. The portable sanitizing wand of claim 16, further comprising abottom cover arranged to fit over the bottom rim. 18-20. (canceled)